The reliability of semiconductor materials with electrical and optical properties are
connected to their structures. The elastic strain field and tilt analysis of the crystal lattice …

Unprecedented tools to image crystalline structure distributions in materials have been
made possible by recent advances in X-ray sources, X-ray optics and X-ray methods …

The ID01 beamline has been built to combine Bragg diffraction with imaging techniques to
produce a strain and mosaicity microscope for materials in their native or operando state. A …

Solid-state reactions play a key role in materials science. The evolution of the structure of a
single 350 nm Ni3Fe nanoparticle, ie, its morphology (facets) as well as its deformation field …

High-brilliance x-ray sources (x-ray free-electron lasers or diffraction-limited storage rings)
allow the visualization of ultrafast processes in a 2D manner using single exposures …

Electronic or catalytic properties can be modified at the nanoscale level. Engineering
efficient and specific nanomaterials requires the ability to study their complex structure …

The current burst of device concepts based on nanoscale domain-control in magnetically
and electrically ordered systems motivates us to review the recent development in the …

The necessity of map** crystal defects in battery materials after synthesis is crucial in
understanding heterogeneity within a single crystal domain and among particles to develop …

Studying model nanoparticles is one approach to better understand the structural evolution
of a catalyst during reactions. These nanoparticles feature well‐defined faceting, offering the …

Strain engineering is a promising technology with potential application in memory devices,
electronic elements, photoactive materials, etc. Nanoscale imaging of the strain is therefore …